/*
    Copyright 2005-2013 Intel Corporation.  All Rights Reserved.

    This file is part of Threading Building Blocks.

    Threading Building Blocks is free software; you can redistribute it
    and/or modify it under the terms of the GNU General Public License
    version 2 as published by the Free Software Foundation.

    Threading Building Blocks is distributed in the hope that it will be
    useful, but WITHOUT ANY WARRANTY; without even the implied warranty
    of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
    GNU General Public License for more details.

    You should have received a copy of the GNU General Public License
    along with Threading Building Blocks; if not, write to the Free Software
    Foundation, Inc., 51 Franklin St, Fifth Floor, Boston, MA  02110-1301  USA

    As a special exception, you may use this file as part of a free software
    library without restriction.  Specifically, if other files instantiate
    templates or use macros or inline functions from this file, or you compile
    this file and link it with other files to produce an executable, this
    file does not by itself cause the resulting executable to be covered by
    the GNU General Public License.  This exception does not however
    invalidate any other reasons why the executable file might be covered by
    the GNU General Public License.
*/

#if __TBB_MIC
#pragma offload_attribute (push,target(mic))
#endif // __TBB_MIC

#include <cstdio>
#include <cstdlib>
#include <string>
#include "tbb/atomic.h"
#include "tbb/tick_count.h"
#include "tbb/task_scheduler_init.h"
#include "tbb/task_group.h"

#if __INTEL_COMPILER
// Suppress "std::auto_prt<> is deprecated" warning
// TODO: replace auto_ptr with unique_ptr for compilers supporting C++11
#pragma warning(disable: 1478)
#endif
#include "../../common/utility/utility.h"

#pragma warning(disable: 4996)

#if __INTEL_COMPILER
#define __TBB_LAMBDAS_PRESENT ( _TBB_CPP0X && __INTEL_COMPILER > 1100 )
#elif __GNUC__
#define __TBB_LAMBDAS_PRESENT ( _TBB_CPP0X && __TBB_GCC_VERSION >= 40500 )
#elif _MSC_VER
#define __TBB_LAMBDAS_PRESENT ( _MSC_VER>=1600 )
#endif

const unsigned BOARD_SIZE=81;
const unsigned BOARD_DIM=9;

using namespace tbb;
using namespace std;

atomic<unsigned> nSols;
bool find_one = false;
bool verbose = false;
unsigned short init_values[BOARD_SIZE] = {1,0,0,9,0,0,0,8,0,0,8,0,2,0,0,0,0,0,0,0,5,0,0,0,7,0,0,0,5,2,1,0,0,4,0,0,0,0,0,0,0,5,0,0,7,4,0,0,7,0,0,0,3,0,0,3,0,0,0,2,0,0,5,0,0,0,0,0,0,1,0,0,5,0,0,0,1,0,0,0,0};
task_group *g;
double solve_time;

typedef struct {
    unsigned short solved_element;
    unsigned potential_set;
} board_element;

void read_board(const char *filename) {
    FILE *fp;
    int input;
    fp = fopen(filename, "r");
    if (!fp) { 
        fprintf(stderr, "sudoku: Could not open input file '%s'.\n", filename);
        exit(1);
    }
    for (unsigned i=0; i<BOARD_SIZE; ++i) {
        if (fscanf(fp, "%d", &input))
            init_values[i] = input;
        else {
            fprintf(stderr, "sudoku: Error in input file at entry %d, assuming 0.\n", i);
            init_values[i] = 0;
        }
    }
    fclose(fp);
}

void print_board(board_element *b) {
    for (unsigned row=0; row<BOARD_DIM; ++row) {
        for (unsigned col=0; col<BOARD_DIM; ++col) {
            printf(" %d", b[row*BOARD_DIM+col].solved_element);
            if (col==2 || col==5) printf(" |");
        }
        printf("\n");
        if (row==2 || row==5) printf(" ---------------------\n");
    }
}

void print_potential_board(board_element *b) {
    for (unsigned row=0; row<BOARD_DIM; ++row) {
        for (unsigned col=0; col<BOARD_DIM; ++col) {
            if (b[row*BOARD_DIM+col].solved_element) 
                printf("  %4d ", b[row*BOARD_DIM+col].solved_element);
            else
                printf(" [%4d]", b[row*BOARD_DIM+col].potential_set);
            if (col==2 || col==5) printf(" |");
        }
        printf("\n");
        if (row==2 || row==5)
            printf(" ------------------------------------------------------------------\n");
    }
}

void init_board(board_element *b) {
    for (unsigned i=0; i<BOARD_SIZE; ++i)
        b[i].solved_element = b[i].potential_set = 0;
}

void init_board(board_element *b, unsigned short arr[81]) {
    for (unsigned i=0; i<BOARD_SIZE; ++i) {
        b[i].solved_element = arr[i]; 
        b[i].potential_set = 0;
    }
}

void init_potentials(board_element *b) {
    for (unsigned i=0; i<BOARD_SIZE; ++i)
        b[i].potential_set = 0;
}

void copy_board(board_element *src, board_element *dst) {
    for (unsigned i=0; i<BOARD_SIZE; ++i)
        dst[i].solved_element = src[i].solved_element;
}

bool fixed_board(board_element *b) {
    for (int i=BOARD_SIZE-1; i>=0; --i)
        if (b[i].solved_element==0) return false;
    return true;
}

bool in_row(board_element *b, unsigned row, unsigned col, unsigned short p) {
    for (unsigned c=0; c<BOARD_DIM; ++c)
        if (c!=col && b[row*BOARD_DIM+c].solved_element==p)  return true;
    return false;
}

bool in_col(board_element *b, unsigned row, unsigned col, unsigned short p) {
    for (unsigned r=0; r<BOARD_DIM; ++r)
        if (r!=row && b[r*BOARD_DIM+col].solved_element==p)  return true;
    return false;
}

bool in_block(board_element *b, unsigned row, unsigned col, unsigned short p) {
    unsigned b_row = row/3 * 3, b_col = col/3 * 3;
    for (unsigned i=b_row; i<b_row+3; ++i)
        for (unsigned j=b_col; j<b_col+3; ++j)
            if (!(i==row && j==col) && b[i*BOARD_DIM+j].solved_element==p) return true;
    return false;
}

void calculate_potentials(board_element *b) {
    for (unsigned i=0; i<BOARD_SIZE; ++i) {
        b[i].potential_set = 0;
        if (!b[i].solved_element) { // element is not yet fixed
            unsigned row = i/BOARD_DIM, col = i%BOARD_DIM;
            for (unsigned potential=1; potential<=BOARD_DIM; ++potential) {
                if (!in_row(b, row, col, potential) && !in_col(b, row, col, potential)
                    && !in_block(b, row, col, potential))
                    b[i].potential_set |= 1<<(potential-1);
            }
        }
    }
}

bool valid_board(board_element *b) {
    bool success=true;
    for (unsigned i=0; i<BOARD_SIZE; ++i) {
        if (success && b[i].solved_element) { // element is fixed
            unsigned row = i/BOARD_DIM, col = i%BOARD_DIM;
            if (in_row(b, row, col, b[i].solved_element) || in_col(b, row, col, b[i].solved_element) || in_block(b, row, col, b[i].solved_element))
                success = false;
        }
    }
    return success;
}

bool examine_potentials(board_element *b, bool *progress) {
    bool singletons = false;
    for (unsigned i=0; i<BOARD_SIZE; ++i) {
        if (b[i].solved_element==0 && b[i].potential_set==0) // empty set
            return false;
        switch (b[i].potential_set) {
        case 1:   { b[i].solved_element = 1; singletons=true; break; }
        case 2:   { b[i].solved_element = 2; singletons=true; break; }
        case 4:   { b[i].solved_element = 3; singletons=true; break; }
        case 8:   { b[i].solved_element = 4; singletons=true; break; }
        case 16:  { b[i].solved_element = 5; singletons=true; break; }
        case 32:  { b[i].solved_element = 6; singletons=true; break; }
        case 64:  { b[i].solved_element = 7; singletons=true; break; }
        case 128: { b[i].solved_element = 8; singletons=true; break; }
        case 256: { b[i].solved_element = 9; singletons=true; break; }
        }
    }
    *progress = singletons;
    return valid_board(b);
}

#if !__TBB_LAMBDAS_PRESENT
void partial_solve(board_element *b, unsigned first_potential_set);

class PartialSolveBoard {
    board_element *b;
    unsigned first_potential_set;
public:
    PartialSolveBoard(board_element *_b, unsigned fps) :
        b(_b), first_potential_set(fps) {}
    void operator() () const {
        partial_solve(b, first_potential_set);
    }
};
#endif

void partial_solve(board_element *b, unsigned first_potential_set) {
    if (fixed_board(b)) {
        if ( find_one )
            g->cancel();
        if (++nSols==1 && verbose) {
            print_board(b);
        }
        free(b);
        return;
    }
    calculate_potentials(b);
    bool progress=true;
    bool success = examine_potentials(b, &progress);
    if (success && progress) {
        partial_solve(b, first_potential_set);
    } else if (success && !progress) {
        board_element *new_board;
        while (b[first_potential_set].solved_element!=0) ++first_potential_set;
        for (unsigned short potential=1; potential<=BOARD_DIM; ++potential) {
            if (1<<(potential-1) & b[first_potential_set].potential_set) {
                new_board = (board_element *)malloc(BOARD_SIZE*sizeof(board_element));
                copy_board(b, new_board);
                new_board[first_potential_set].solved_element = potential;
#if __TBB_LAMBDAS_PRESENT
                g->run( [=]{ partial_solve(new_board, first_potential_set); } );
#else
                g->run(PartialSolveBoard(new_board, first_potential_set));
#endif
            }
        }
        free(b);
    }
    else {
        free(b);
    }
}

unsigned solve(int p) {
    task_scheduler_init init(p);
    nSols = 0;
    board_element *start_board = (board_element *)malloc(BOARD_SIZE*sizeof(board_element));
    init_board(start_board, init_values);
    g = new task_group;
    tick_count t0 = tick_count::now();
    partial_solve(start_board, 0);
    g->wait();
    solve_time = (tick_count::now() - t0).seconds();
    delete g;
    return nSols;
}

#if __TBB_MIC
#pragma offload_attribute (pop)
#endif // __TBB_MIC

int do_get_default_num_threads() {
    int threads;
    #if __TBB_MIC
    #pragma offload target(mic) out(threads)
    #endif // __TBB_MIC
    threads = tbb::task_scheduler_init::default_num_threads();
    return threads;
}

int get_default_num_threads() {
    static int threads = do_get_default_num_threads();
    return threads;
}

int main(int argc, char *argv[]) {
    try {
        tbb::tick_count mainStartTime = tbb::tick_count::now();

        utility::thread_number_range threads(get_default_num_threads);
        string filename = "";
        bool silent = false;

        utility::parse_cli_arguments(argc,argv,
            utility::cli_argument_pack()
            //"-h" option for for displaying help is present implicitly
            .positional_arg(threads,"n-of-threads",utility::thread_number_range_desc)
            .positional_arg(filename,"filename","input filename")

            .arg(verbose,"verbose","prints the first solution")
            .arg(silent,"silent","no output except elapsed time")
            .arg(find_one,"find-one","stops after finding first solution\n")
        );

        if ( silent ) verbose = false;

        if ( !filename.empty() )
            read_board( filename.c_str() );
        // otherwise (if file name not specified), the default statically initialized board will be used.
        for(int p = threads.first; p <= threads.last; p = threads.step(p) ) {
            unsigned number;
            #if __TBB_MIC
            #pragma offload target(mic) in(init_values, p, verbose, find_one) out(number, solve_time)
            {
            #endif // __TBB_MIC
            number = solve(p);
            #if __TBB_MIC
            }
            #endif // __TBB_MIC

            if ( !silent ) {
                if ( find_one ) {
                    printf("Sudoku: Time to find first solution on %d threads: %6.6f seconds.\n", p, solve_time);
                }
                else {
                    printf("Sudoku: Time to find all %u solutions on %d threads: %6.6f seconds.\n", number, p, solve_time);
                }
            }
        }

        utility::report_elapsed_time((tbb::tick_count::now() - mainStartTime).seconds());

        return 0;
    } catch(std::exception& e) {
        std::cerr<<"error occurred. error text is :\"" <<e.what()<<"\"\n";
        return 1;
    }
};

